Apparatus having curable resin adhering plate-shaped base and cover plate and manufacturing method the same

ABSTRACT

There are provided an apparatus and a method of manufacturing the apparatus. The apparatus includes: a plate-shaped base; a cover plate; and a curable resin adhering the plate-shaped base and the cover plate together. At least one of the plate-shaped base and the cover plate includes a light-shielding member covering a peripheral part of the at least one of the plate-shaped base and the cover plate. In an area which is shielded by the light-shielding member, a part of the curable resin at a side of an inner edge of the light shielding member is lower in one of an elastic modulus, a curing degree, and an adhesion strength than another part of the curable resin at a side of an outer edge of the light shielding member.

TECHNICAL FIELD

The present invention relates to an apparatus and a manufacturing methodof the same. Particularly, the present invention relates to an apparatushaving a structure in which a transparent cover plate and a base, suchas a display unit and a touch sensor, are adhered together with curableresin, and a manufacturing method of the same.

BACKGROUND

In mobile phones, smart phones, touch panels and other devices, whichare equipped with an image display section, the image display sectionhave conventionally employed the following structure (an air gapstructure). That is, an air gap is made between an image display unit,such as a liquid crystal display module, and a transparent cover plateput on top of the image display unit (e.g., a glass plate, atempered-glass plate, an acrylic board, a PET or polyethyleneterephthalate board, and a composite substrate including any of them).Such a structure avoids separation of the cover plate from the imagedisplay unit, which can be occurs because of separation force applied tothe cover plate due to external stress, and avoids display defects dueto external force being applied to the display unit.

In recent years, for the purpose of improving visibility and adhesion ofthe display unit, a part of such devices employs a structure that acover plate and the display unit is adhered with optical elasticityresin which can be cured by light. In apparatuses which are desired tohave enhanced design characteristics and enhanced decorationcharacteristics of the display unit (e.g., a car navigation system and atablet terminal), a cover plate decorated by printing is used, and thescreen size for those apparatuses tends to become larger.

FIG. 24 illustrates a conventional display apparatus disclosed inInternational Patent Application Publication WO2007/066590(corresponding to US2009/162645A1). The conventional display apparatusincludes: a transparent cover plate 21; a light-shielding printed member22 prepared by printing with black ink and arranged on the rear surfaceof the transparent cover plate 21 around the periphery of a display areaof the transparent cover plate 21; a display unit including a TFT (ThinFilm Transistor) substrate 23, a CF (Color Filter) substrate 24, a phasedifference correction film 25, a polarization plate/optical film 26, anda driver IC 27; and a transparent photo-curable resin 28 that bonds thetransparent cover plate 21 and the entire surface of the display unittogether.

The thickness of the photo-curable resin 28 is in the range of 30 μm to200 μm and the protrusion of the photo-curable resin 28 from the outerperiphery of the display unit is within about 0.3 mm. The partsandwiched by the light-shielding printed member 22 and the display unitis not irradiated with light coming from upward of the cover plate ordownward of the display unit. Therefore, light is irradiated from alateral direction of the outer circumference of the cover plate so as tocure the photo-curable resin 28 to have the curing degree of 70% ormore.

FIG. 25 illustrates a structure of a conventional display apparatusdisclosed in Japanese Unexamined Patent Application Publication (JP-A)No. 2013-088455. The conventional display apparatus includes: atransparent cover plate 31; a light-shielding printed member 32 preparedby printing with black ink and arranged on the rear surface of thetransparent cover plate 31 around the periphery of a display area of thetransparent cover plate 31; a display unit including a flat paneldisplay unit 33, a backlight 34 and a bezel 35; a dam section arrangedon an outer-edge area of the transparent cover plate 31; and atransparent photo-curable resin 37 that adheres the transparent coverplate 31 and the entire surface of the display unit together.

The dam section 36 is formed by applying photo-curable material onto thetransparent cover plate 31 in advance to form a bead shape having heightof 150 μm and width of 1 mm and then curing the photo-curable materialby light. A predetermined amount of photo-curable resin 37 is applied onthe inner side of the dam section 36 so as to have the thickness of 150μm, the transparent cover plate 31 is joined together with the displayunit, and the photo-curable resin 37 is fully cured by irradiation of UVlight or the like.

In WO2007/066590, the photo-curable resin 28 on a location sandwiched bythe light-shielding printed member 22 on the transparent cover plate 21and the display unit has a uniform curing degree not less than 70%. Inaddition, in JP-A No. 2013-088455, the photo-curable resin 37 has auniform curing degree and is fully cured.

In WO2007/066590 and JP-A No. 2013-088455, photo-curable resin on alocation sandwiched by the transparent cover plate and the display unitis cured to have a uniform high curing degree. Accordingly, when thetransparent cover plate is deformed by external force, such adeformation makes the stress applied to the display area to causedisplay defect. In addition, under the condition that the photo-curableresin is cured with a uniform curing degree to have a low curing degree,such a condition can make a problem that external force can separate thetransparent cover plate from the display unit.

In addition, the dam section 36 is provided to avoid the photo-curableresin 37 from flowing outside the display unit and therefore the resindoes not reach to the end of the display unit in JP-A No. 2013-088455.Thus, there are issues of the transparent cover plate 31 is easilyseparated from the display unit as a result of external force from theend of the transparent cover plate 31. Such a condition can make aproblem that external force applied from the end of the transparentcover plate 31 can easily remove the transparent cover plate from thedisplay unit.

The present invention seeks to solve the problems.

SUMMARY

In view of the above-mentioned problems, there are provided illustrativeapparatuses and illustrative manufacturing methods of such an apparatus,as embodiments of the present invention. The illustrative apparatus canbe a display apparatus, and avoids occurrence of display defects due toexternal force and further avoids a cover plate from being separatedfrom the display unit.

The present invention is directed to an apparatus comprising: aplate-shaped base; a cover plate; a curable resin located in a gapbetween the plate-shaped base and the cover plate and adhering theplate-shaped base and the cover plate together; and a light-shieldingmember located on a peripheral part of at least one of the plate-shapedbase and the cover plate. The curable resin includes a firstcurable-resin part, a second curable-resin part, and a thirdcurable-resin part. In an area in the gap, which is shielded by thelight-shielding member, the first curable-resin part is located at aside of an outer edge of the light-shielding member and the secondcurable-resin part is located at a side of an inner edge of thelight-shielding member. In an inner area in the gap, which is surroundedby the light-shielding member, the third curable-resin part is located.The second-curable resin part is lower in one of an elastic modulus, acuring degree, and an adhesion strength than the first-curable resinpart.

The present invention is directed to a method of manufacturing anapparatus including a plate-shaped base, a cover plate, a curable resinadhering the plate-shaped base and the cover plate together, and alight-shielding member located on a peripheral part of at least one ofthe plate-shaped base and the cover plate. The method comprises:adhering the plate-shaped base and the cover plate together, by applyingthe curable resin onto at least one of the plate-shaped base and thecover plate, and adjusting positions of the plate-shaped base and thecover plate; curing the curable resin in an entire of an area, which isshielded by the light-shielding member, in a gap between theplate-shaped base and the cover plate; and curing the curable resin onlyin an outer-edge part of the area, which is shielded by thelight-shielding member, in the gap. After both of the curing the curableresin in the entire of the area in the gap and the curing the curableresin only in the outer-edge part of the area in the gap, the curableresin in an inner-edge part of the area in the gap is lower in one of anelastic modulus, a curing degree, and an adhesion strength than thecurable resin in the outer-edge part of the area in the gap.

Other features of illustrative embodiments will be described below.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments will now be described, by way of example only, withreference to the accompanying drawings which are meant to be exemplary,not limiting, and wherein like elements numbered alike in severalfigures, in which:

FIG. 1A and FIG. 1B depict a plan view and a sectional view illustratingan example of a display apparatus (having a structure using a liquidcrystal panel for the base) of Example 1;

FIG. 2A and FIG. 2B depict a half sectional view illustrating an exampleof a display apparatus (having a structure using a liquid crystal panelfor the base) of Example 1 and a graph of the curing degree;

FIGS. 3A and 3B depict a half sectional view of another example of adisplay apparatus in which curable resin is in an ideal cured state, anda graph of the curing degree;

FIG. 4A depicts a graph illustrating an example of curing degree vscuring depth characteristics of the curing resin for various wavelengthsof curing light and the integrated amount of irradiated light;

FIG. 4B and FIG. 4C depict a half sectional view of another example of adisplay apparatus (having a structure that the curing degree of curableresin in a gap changes step-wise) of Example 1 and a graph of the curingdegree;

FIG. 5A and FIG. 5B depict a half sectional view of another example of adisplay apparatus (having a structure that the gap is filled withphoto-curable resin up to the end of the base) of Example 1 and a graphof the curing degree;

FIG. 6A and FIG. 6B depict a half sectional view of another example of adisplay apparatus (having a structure that photo-curable resin in thegap having the increased curing degree up to a position of the outeredge of the seal) of Example 1 and a graph of the curing degree;

FIG. 7A and FIG. 7B depict a half sectional view of another example of adisplay apparatus (having a structure employing a cover panel with atouch sensor, for the cover panel) of Example 1 and a graph of thecuring degree;

FIG. 8A and FIG. 8B depict a half sectional view of another example of adisplay apparatus (having a structure employing a liquid crystal panelwith a touch sensor, for the base) of Example 1 and a graph of thecuring degree;

FIG. 9A and FIG. 9B depict a half sectional view of another example of adisplay apparatus (having a structure employing a transparent touchsensor, for the base) of Example 1 and a graph of the curing degree;

FIG. 10A and FIG. 10B depict a half sectional view of another example ofa display apparatus (having a structure employing a transparent coverplate for the cover plate) of Example 1 and a graph of the curingdegree;

FIGS. 11A to 11D depict half sectional views schematically illustratinga method of manufacturing a display apparatus of Example 1;

FIGS. 12A to 12D depict half sectional views schematically illustratinganother method of manufacturing a display apparatus of Example 1;

FIGS. 13A to 13D depict side half sectional views schematicallyillustrating another method of manufacturing a display apparatus ofExample 1, using heat-curable resin for the curable resin;

FIGS. 14A to 14D depict side half sectional views schematicallyillustrating another method of manufacturing a display apparatus ofExample 1, using hybrid curable resin having moisture curability for thecurable resin;

FIGS. 15A to 15D depict diagrams partial plan view and half sectionalview of a display apparatus for illustrating examples that externalforce in the direction of pulling and separating the cover plate fromthe base is applied to the cover plate adhered to the base;

FIGS. 16A to 16D depict diagrams partial plan view and half sectionalview of a display apparatus for illustrating examples that externalforce in the direction of pressing the cover plate is applied to thecover plate;

FIG. 17A and FIG. 17B depict a plan view and a sectional viewillustrating an example of a display apparatus (having a structure usinga LCD module for the base) of Example 2;

FIG. 18A and FIG. 18B depict a half sectional view of an example of adisplay apparatus (having a structure using a LCD module for the base)of Example 2 and a graph of the curing degree;

FIG. 19A and FIG. 19B depict a plan view and a sectional viewillustrating an example of a display apparatus (having a structure usinga gap-forming member put between the base and the cover plate) ofExample 3;

FIG. 20A and FIG. 20B depict a half sectional view of an example of adisplay apparatus (having a structure using a gap-forming member putbetween the base and the cover plate) of Example 3 and a graph of thecuring degree;

FIG. 21A and FIG. 21B depict a plan view and a half sectional viewillustrating another example of a display apparatus (having a structurethat a liquid crystal panel is employed for the base and the curingdegree of curable resin within a display region is higher than that ofthe curable resin at the side of outer edge of light-shielding member,namely the edge part) of Example 4 and a graph of the curing degree;

FIG. 22A and FIG. 22B depict a plan view and a half sectional viewillustrating another example of a display apparatus (having a structurethat a liquid crystal panel is employed for the base, and the curingdegree of curable resin within a display region is lower than that ofthe curable resin at the side of the outer edge of light-shieldingmember, namely the edge part and is higher than that of the curableresin in the vicinity of the display region, namely the inner part) ofExample 4 and a graph of the curing degree;

FIG. 23A and FIG. 23B depict a plan view and a half sectional viewillustrating another example of a display apparatus (having a structurethat UV rays, which once cured the curable resin in the display region,further entered an area below the light-shielding member to cure thecurable resin in the area) of Example 4 and a graph of the curingdegree;

FIG. 24 depicts a diagram illustrating a conventional display apparatus(WO2007/066590); and

FIG. 25 depicts a diagram illustrating a conventional display apparatus(JP-A No. 2013-088455).

DETAILED DESCRIPTION

Illustrative apparatuses and illustrative manufacturing methods of suchan apparatus will be described below as embodiments of the presentinvention with reference to the drawings. It will be appreciated bythose of ordinary skill in the art that the description given hereinwith respect to those figures is for exemplary purposes only and is notintended in any way to limit the scope of potential embodiments may beresolved by referring to the appended claims.

According to illustrative apparatuses and illustrative manufacturingmethods as embodiments of the present invention, there can be provided adisplay apparatus in which the entire surface of a base including animage display region is adhered to a cover plate including alight-shielding member by using curable resin. The display apparatus canavoid separation of the cover plate from the base because of externalforce. Further, the display apparatus can reduce the stress, which comesfrom deformation of the cover plate due to external force, applied tothe display region, and reduce display defects.

As described in the background, there have been provided apparatusesemploying a structure that a cover plate and a display unit is adheredtogether with optical elasticity resin which can be cured by light. Inconventional structures, photo-curable resin is cured to have a uniformand high curing degree. In such structures, deformation of a cover platedue to external force can cause the stress to be applied to a displayregion and then cause display defects in the display region. On theother hand, in a structure that a photo-curable resin is cured to have auniform and low curing degree, such a structure can cause separation ofthe cover plate from the base because of external force, which is aproblem. In another structure using dam section 36 to preventphoto-curable resin 37 from spilling out, as disclosed in JP-A No.2013-088455, such a structure can easily cause separation of a coverplate from a display unit because of external force applied from theedge of the cover plate, which is also a problem.

In view of the problems, as one embodiment of the present invention,there is provided an apparatus including a plate-shaped base; a coverplate; a curable resin adhering the base and the cover plate together;and a light-shielding member covering a peripheral part of at least oneof the plate-shaped base and the cover plate. The curable resin has beencured to include a first curable-resin part, a second curable-resinpart, and a third curable-resin part. In an area in the gap, which isshielded by the light-shielding member, the first curable-resin part islocated at a side of an outer edge of the light-shielding member and thesecond curable-resin part is located at a side of an inner edge of thelight-shielding member. In an inner area in the gap, which is surroundedby the light-shielding member, the third curable-resin part is located.The second-curable resin part is lower in one of an elastic modulus, acuring degree, and an adhesion strength than the first-curable resinpart.

As a concrete example of the above embodiment, there is provided anapparatus, such as a display apparatus, including a cover plate having alight-shielding member; a base having a display region; and curableresin put between the cover plate and the base to adhere the entiresurface of the base onto the cover plate. In the apparatus, the curableresin is cured not to have a uniform and high curing degree but is curedsuch that a part of the curable resin located between thelight-shielding member on the cover plate and the display unit, is in anon-fluid state in the vicinity of the inner edge of the light-shieldingmember (in an inner curable-resin part), and to have the lower curingdegree in the vicinity of the inner edge of the light-shielding member(in an inner curable-resin part) in comparison with the curing degree atthe side of the outer edge of the light-shielding member (in an edgecurable-resin part). Such a structure reduces the stress to be appliedto the display region, which coming from a deformation of the coverplate due to eternal force, and reduces display defects to be caused inthe display region. Further, such a structure further restrictsseparation of the cover plate from the display unit because of externalforce. Hereafter, such apparatuses and manufacturing methods will bedescribed in detail with reference to the drawings.

Example 1

First, an apparatus and a manufacturing method of the apparatusaccording to Example 1 will be described with reference to FIGS. 1A to16D. The present example provides an example that the structure of theabove-described embodiment is applied to the following displayapparatus. The display apparatus includes a base which uses liquidcrystal panel 1 for an image display region; cover plate 2 includinglight-shielding member 3; and curable resin 4 which is photo-curableresin. The entire surface of the base is adhered to the cover plate 2with the photo-curable resin 4. Hereinafter, the structure of Example 1will be described with reference to FIGS. 1A to 2B.

FIG. 1A is a plan view of the display apparatus, and FIG. 1B is asectional view of the display apparatus, taken along the line IB-IB inFIG. 1A. FIG. 2A and FIG. 2B are a half sectional view of the displayapparatus and a graph of an example of the curing degree of the curableresin with respect to distance along a gap between the base and thecover plate 2.

The base can be an image display device, such as a flat panel display, aliquid crystal display unit, a liquid crystal panel, and an LCD (LiquidCrystal Display) module. A liquid crystal panel is used for the base inthis example.

The base is liquid crystal panel 1 including display region 1 e fordisplaying images; and wiring region 1 d surrounding the display region1 e, for supplying display signals. The display region 1 e includes TFTelements, RGB pixels (red, green, and blue pixels) and a BM (blackmatrix) pattern which are formed thereon, and displays images on thebasis of the display signals. The wiring region 1 d includes wiring forsupplying display signals to the TFT elements. Since the wiring isformed using a metallic film or the like, it does not transmit light.The wiring region 1 d further includes a light-shielding film forblocking light coming from a backlight.

The liquid crystal panel 1 as the base includes TFT substrate 1 b,color-filter substrate 1 a, seal 1 g, liquid crystal 1 f, andpolarization plates and optical compensation films 1 c. On the TFTsubstrate 1 b, TFT elements and other elements are patterned. On thecolor-filter substrate 1 a, RGB pixels, a black matrix pattern and otherelements are patterned. The seal 1 g joins the TFT substrate 1 b and thecolor-filter substrate together and makes an arbitrary space insideitself. The liquid crystal 1 f fills a gap between the TFT substrate 1 band color-filter substrate 1 a (in other words, is sealed in the spaceinside the seal 1 g). The polarization plates and optical compensationfilms 1 c are adhered on the top surface and the rear surface of thejoined substrates.

The cover plate 2, on which the light-shielding member 3 is arranged,can be a substrate made of transparent glass, a substrate made oftempered glass, a substrate made of plastics, such as an acrylic boardand a PET board, and a composite substrate made of any of them. Thecover plate 2 includes light-shielding region 2 a and light-transmissionregion 2 b. The light-transmission region 2 b is a part of the coverplate 2, corresponding to the display region 1 e of the base, under thecondition that the cover plate 2 and the base are adhered together. Inthe other part of the cover plate 2, there is arranged thelight-shielding member 3 made of black ink with light-blocking effect tocover the outer edge part (peripheral part) of the cover plate 2, andthe light-shielding member 3 shields the outer edge part from light toform the light-shielding region 2 a having a belt-like shape. It shouldbe noted that the light-shielding member 3 of the present example isformed of black ink, but any material having light-blocking effect(e.g., color ink) or any surface treatment (e.g., forming a reflectionfilm) can be used for forming the light-shielding member 3,alternatively.

Examples of the curable resin 4 used for adhering together the base andthe cover plate 2 having the light-shielding member 3, includephoto-curable resin, heat-curable resin, moisture-curable resin, andhybrid curable resin having plural types of curing function of, forexample, photo-curable resin, heat-curable resin, and moisture-curableresin (photo-curability, heat-curability, and moisture-curability).Herein, photo-curable resin is used for describing the present example.

The photo-curable resin located in the gap between the cover plate 2 andthe base is resin which can be cured (hardened) by light. Thephoto-curable resin includes an edge curable-resin part 4 a located atthe side of the outer edge of the light-shielding member 3 (a firstcurable-resin part); an inner curable resin part located at the side ofthe inner edge (in the vicinity of the inner edge) of thelight-shielding member 3 (a second curable-resin part); and a curableresin part located within an area in the gap corresponding to inlight-transmission region 2 b inside the light-shielding member 3 (athird curable-resin part). The photo-curable resin is cured such thatthese curable resin parts have the curing degrees after a curingprocess, as follows. The curing degree, which is obtained after a curingprocess, of the inner curable-resin part 4 b located nearby the displayregion 1 e of the base and in the vicinity 3 b (inner part) of the inneredge of the light-shielding member 3, differs from the curing degree,which is obtained after a curing process, of the edge curable-resin part4 a located a side 3 a of the outer edge of the light-shielding member 3(edge part). That is, the inner curable-resin part 4 b is lower incuring degree after a curing process than the edge curable-resin part 4a. The method of curing the curable resin 4 in the gap will be given inthe manufacturing method described later.

It is preferable that, as illustrated in FIGS. 2A and 2B, the curingdegree after a curing process of the inner curable-resin part 4 blocated nearby the display region 1 e of the base and in the vicinity 3b of the inner edge of the light-shielding member 3 is about 60%, whichis in a non-fluidized cured state (the definition of “non-fluidized”will be described later), and the curing degree after a curing processof the edge curable-resin part 4 a is equal to 80% or more, which is ina cured state. In the present example, the curing degree of the edgecurable-resin part 4 a and the inner curable-resin part 4 b decreasescontinuously or gradually from the edge part to the inner part (from anend of the first curable-resin part at the side of the outer edge of thelight-shielding member to an end of the second curable-resin part at theside of the inner edge of the light-shielding member), as illustrated inFIG. 2B, where the inner part represents a part of the curable resin inthe vicinity 3 b of the inner edge of the light-shielding member 3, andthe edge part represents a part of the curable resin at the side 3 a ofthe outer edge of the light-shielding member 3. The ideal cured state isthat, as illustrated in FIGS. 3A and 3B, the curing degree of the edgecurable-resin part 4 a and the inner curable-resin part 4 b changesstep-wise from the edge part to the inner position.

A step-wise profile of the curing degree can be obtained by preparingtwo or more kinds of UV rays having different wavelengths for a curingprocess and by selectively controlling the wavelength of the UV rays andthe illuminance level of UV rays of the selected wavelengths. Forexample, it is considered a way to form a structure illustrated in FIGS.4B and 4C such that the edge curable-resin part 4 a extends to thelength of 10 millimeters from the end of the curable resin 4 at the side3 a of the outer edge of the light-shielding member 3 and the innercurable-resin part 4 b extends from the position 10 millimeters awayfrom the end of the curable resin 4 to the position 20 mm from the endof the curable resin 4. In this structure, the step-wise profile of thecuring degree as illustrated in FIG. 4C can be achieved by the followingprocesses. In advance of curing processes, the curing conditions of thecurable resin are confirmed for wavelengths of curing light andilluminance levels of curing light with each of the wavelengths, asillustrated in FIG. 4A. FIG. 4A shows an example of curing degree vscuring depth characteristics of the curing resin for short and longwavelengths of curing light and for HIGH, MIDDLE and LOW illuminancelevels (the integrated amount of the irradiated light) of curing lightwith each of the wavelengths. On the basis of the confirmation result,the curable resin is irradiated with curing light with a long wavelength(for example, 400 nm), which is effective to cure the innercurable-resin part 4 b, at the MEDIUM illuminance level, to form theinner curable-resin part 4 b, and is further irradiated with light witha short wavelength (for example, 360 nm), which is effective to cure theedge curable-resin part 4 a, at the HIGH illuminance level, to form theedge curable-resin part 4 a.

It should be noted that, as illustrated in FIGS. 5A and 5B, by fillingthe gap between the light-shielding member 3 on the cover plate 2 andthe wiring region 1 d of the base with photo-curable resin up to the endof the base, it is possible to restrict deterioration of thepolarization plates and optical compensation films 1 c adhered on thetop surface and the rear surface of the liquid crystal panel 1 as thebase.

Further, as illustrated in FIG. 5, even in the structure that thelight-shielding member 3 on the cover plate 2 does not extend to theouter peripheral edge of the cover plate 2, but extends to the midwaybetween the end of the transparent region 2 b and the outer peripheraledge of the cover plate 2 so as to block light, it is possible to curethe curable resin 4 such that the curing degree after a curing processof the inner curable-resin part 4 b is lower than that of the edgecurable-resin part 4 a.

In the liquid crystal panel 1, liquid crystal 1 f fills a spacepartitioned by the seal 1 g in the gap between the TFT substrate 1 b andthe color-filter substrate 1 a, and the liquid crystal 1 f is in afluidized state. If external force is applied to the space filled withthe liquid crystal 1 f, such external force can easily vary the gap andcause display defects. In view of that, the second curable-resin part islocated in the gap to cover an area from the inner edge of thelight-shielding member 3 on the cover plate 2 to an inner edge of theseal, and the first curable-resin part is located in the gap to cover anarea extending from the inner edge of the seal toward the outer edge ofthe light-shielding member 3 (to the end of the curable resin 4 at theside of the outer edge of the light-shielding member 3). In order to theexternal force, the inner curable-resin part 4 b may have the lowercuring degree after a curing process, in comparison with the curingdegree of the other part of the curable resin 4 located in the gap ofthe light-shielding member 3 on the cover plate 2 and the wiring region1 d of the base, as illustrated in FIGS. 6A and 6B. Such a structure canavoid occurrence of display defects in the liquid crystal panel 1 as thebase because of external force. It should be noted that the position tocure the curable resin such that the curing degree after a curingprocess of the edge curable-resin part 4 a is higher than that of theinner curable-resin part 4 b may be located in a part of the curableresin surrounding the display region 1 e.

Although structures that liquid crystal panel 1 is used for the base anda plate with light-shielding member 3 is used for the cover plate 2 havebeen described above, there may be provided a structure that a substrateincluding touch sensor 5 is used for the base or the cover plate 2 so asto add an input function of a touch panel. For example, there can beprovided a structure employing cover plate 6 with a touch sensor,prepared by adding touch sensor 5 onto a cover plate, as illustrated inFIGS. 7A and 7B, or a structure employing liquid crystal panel 7 with atouch sensor, prepared by adding touch sensor 5 onto a liquid crystalpanel as the base, as illustrated in FIGS. 8A and 8B.

Although structures that each of the base and the cover plate 2 includesa light-shielding section, which can block light, have been describedabove, there may be provided a structure that any one of the base andthe cover plate 2 includes such a light-shielding section. For example,there can be provided a structure employing touch sensor 5 for the basewithout a light-shielding section as illustrated in FIGS. 9A and 9B, ora structure employing cover plate 2 without a light-shielding section asillustrated in FIGS. 10A and 10B.

In order to confirm effects of the display apparatuses described above,the inventors have confirmed, by using photo-curable resin cureduniformly, the curing degree and the adhesion strength to the coverplate against external force. The result is shown in the following Table1.

The curing degree of the photo-curable resin in Table 1 was calculatedas follows. There were prepared curable resin before irradiation oflight and curable resin after irradiation of light, and a resincomposition contained in the curable resin before the irradiation and aphoto-curable component (e.g., vinyl group C═C) contained in the curableresin after the irradiation were extracted from spectra measured withinstrument such as a FT-IR spectrometer. The peak intensity (P₀) of theresin composition contained in the curable resin before the irradiationand the peak intensity (P₁) of the photo-curable component contained inthe curable resin after the irradiation were obtained, and then thecuring degree of the curable resin after the irradiation was calculatedwith Expression (1) below.Curing degree (%)=((P ₀ −P ₁)/P ₀)×100  (1)

The photo-curable resin having the curing degree of 80% or moreexhibited the adhesion strength of 0.24 N/mm² or more, and thephoto-curable resin having the curing degree of 60% or less exhibitedthe adhesion strength of 0.15 N/mm² or less. The photo-curable resinhaving the curing degree of 80% exhibited the adhesion strength of 1.6times that of the photo-curable resin having the curing degree of 60%.The greater adhesion strength can be obtained by raising the curingdegree. The photo-curable resin having the curing degree of around 100%exhibited the adhesion strength of 0.32 N/mm² or more.

The appearance condition by external force in Table 1 is determined byseparation of the end, existence of air bubbles in the display region,and occurrence of liquid leakage. The condition is “C” when air bubblesare produced and liquid leakage is caused. The condition is “B” whenthere is separation but no air bubbles in the display region and noliquid leakage. The condition is “A” when there is no separation, no airbubbles, and no liquid leakage.

TABLE 1 Appearance condition due to Curing degree of Adhesion strengthexternal force (occurrence of photo-curable resin (N/mm²) separation orthe like) 100%  0.34-0.37 A 90% 0.33-0.36 A 80% 0.30-0.33 A 70%0.10-0.30 B Less than 60% not more than 0.2 C Less than 50% not morethan 0.1 C

Further, the inventors have confirmed, by using photo-curable resincured uniformly, the curing degree, the elastic modulus, and theinfluence of external force on the displaying condition. The result isshown in the following Table 2.

In Table 2, the conditions of the photo-curable resin are represented asfollows assuming that temperature of usage environment or storingenvironment (e.g., about 25° C.) and the installation condition (e.g.,portrait installation): The condition where the photo-curable resinflows out from the gap in an uncured state or a low curing state is“fluidized” (=B); and the condition where the curing reaction hasadvanced and the photo-curable resin does not flow out of the gap is“non-fluidized” (=A).

The displaying conditions due to external force are represented asfollows: The condition is “C” when there is notable pressing unevennessor the like; “B” when there is slight pressing unevenness or the like;and “A” when the condition is good and there is no development ofpressing unevenness or the like.

The photo-curable resin having the curing degree of 80% or moreexhibited a non-fluidized state and the elastic modulus of 7 KPa ormore, the photo-curable resin having the curing degree of 60% exhibiteda non-fluidized state and the elastic modulus of 5 KPa or less. However,the photo-curable resin having the curing degree of 50% became in afluidized state (elastic modulus is 1 KPa or less) and flowed out fromthe gap between the base and the cover plate. Further, if the curableresin is cured to have the curing degree of 80% or more, the displayingcondition of the liquid crystal display unit used in the base gets worsedue to external force causing pressing unevenness, and if the curableresin is cured to have the curing degree is 60% or less, it is hard tosee the pressing unevenness.

TABLE 2 Curing Displaying condition degree of Elastic due to externalforce photo- Condition of photo- modulus (e.g., pressing curable resincurable resin (KPa) unevenness) 100% non-fluidized = A 11-13 C 90%non-fluidized = A  9-11 C 80% non-fluidized = A 7-9 C 70% non-fluidized= A 5-7 B 60% non-fluidized = A 2-5 A 50% fluidized = B 1 or less A

As the display apparatus the present example illustrated in FIGS. 3A and3B, in the case that the photo-curable resin at the inner part in thegap between the light-shielding member 3 of the cover plate 2 and thewiring region 1 d of the base was cured to have the curing degree ofaround 60% and be in a non-fluidized curing state, and that thephoto-curable resin at the edge part is cured to have the curing degreeof 80% or more and be in a curing state, the adhesion strength was 0.31N/mm² and thus it was possible to obtain a good result with respect tothe displaying condition due to external force. Further, thephoto-curable resin at the inner part has the elastic modulus of 5 KPaor less and thus it was possible to obtain a good result with respect tothe displaying condition due to external force.

It should be noted that a structure that defines the condition of thecurable resin 4 according to the curing degree has been described inthis example. However, when the curing degree is high, the elasticmodulus and adhesion strength are generally high, and when the curingdegree is low, the elastic modulus and adhesion strength are low.Accordingly, with respect to the elastic modulus, the curable resin wascured such that the elastic modulus after being cured of the innercurable-resin part 4 b is lower than the elastic modulus after beingcured of the edge curable-resin part 4 a. With respect to the adhesionstrength, the curable resin was cured such that the adhesion strengthafter being cured of the edge curable-resin part 4 a is larger than theadhesion strength after being cured of the inner curable-resin part 4 b.

Although the above-described Table 1 and Table 2 are evaluation resultsof photo-curable resin, the curable resin 4 of this example is notlimited to photo-curable resin, and structures such as of this examplecan be achieved by controlling the curing state based on characteristicsas shown in the tables also in the curable resin 4 of other type, suchas heat-curable resin and hybrid curable resin.

Next, a manufacturing method of the display apparatus in a case wherethe structure of the display apparatus as an embodiment of the presentinvention is applied to a display apparatus in which the entire surfaceof the base using the liquid crystal panel 1 for the image displayregion is adhered to the cover plate 2 having the light-shielding member3 with the curable resin 4 which is photo-curable resin will bedescribed with reference to FIGS. 11A to 11D.

First, as shown in FIG. 11A, the base and the cover plate 2 are adheredtogether with uncured curable resin 4 d by applying photo-curable resinonto at least one of the liquid crystal panel 1 as the base and thecover plate 2 having the light-shielding member 3; adjusting positionsof the base and the cover plate 2. In order to prevent, for example,displacement at the time of conveying to the next step after adhering,the photo-curable resin may be temporarily cured partially.

Techniques for applying photo-curable resin are not limited inparticular. Examples include: techniques that use a dispenser, a coater,and printing. Among those techniques, the technique that uses adispenser is preferable from the point of controlling the amount ofapplication and preventing incorporation of air bubbles upon adhesion.

In addition, techniques for adjusting positions of the base and thecover plate 2 are not limited in particular. Examples include: atechnique of positioning by external shape reference, and an imageprocessing positioning technique that adjusting the positions of apattern of the light shielding member on the cover plate 2 and apositioning mark for adhesion (not illustrated) provided on the liquidcrystal panel 1 of the base, by using image processing. Among thosetechniques, the image processing positioning technique is preferablefrom the point of positioning accuracy.

In addition, techniques for adhering together the base and the coverplate 2 are not limited in particular. For example, with respect toadhering environment, the following techniques can be used: a techniqueof adhering them together under ordinary pressure, and a technique ofadhering them together under vacuum. With respect to adhering methods,the following techniques can be used: a technique of adhering themtogether with rollers, and a technique of adhering them together withparallel plates. Among those techniques, the technique of adheringtogether with the parallel plate under vacuum is preferable from theviewpoint of preventing air bubbles at the time of adhering.

Next, as shown in FIG. 11B, the adhered body is irradiated with UV rays8 from upward of the cover plate 2 or downward of the base such that thephoto-curable resin located below the light-transmission region 2 b ofthe cover plate 2 is cured (cured curable resin 4 e). FIG. 11B shows anexample of the irradiation from upward of the cover plate 2.

Techniques of curing photo-curable resin below the light-transmissionregion 2 b of the cover plate 2 are not limited in particular. Examplesinclude: a technique of placing the cover plate 2 and the base, whichare adhered together, with the cover plate 2 on the upper side andcollectively irradiating them with a UV lamp arranged above the coverplate 2; a technique of irradiating by scanning uniformly with a spot UVlamp; and a technique of placing the cover plate 2 and the base with thecover plate 2 on the lower side and irradiating them with a UV lamparranged beneath the cover plate 2 while conveying them with a conveyor.Among those techniques, the technique of irradiating the cover plate 2and the base with a UV lamp while conveying them by a conveyor ispreferable from the viewpoint of homogeneousness of the curing state ofthe curable resin after the irradiation.

Next, as shown in FIG. 11C, photo-curable resin is cured with UV light 8to up to the inner portion in the gap between the light-shielding member3 of the cover plate 2 and the wiring region 1 d of the base (curableresin 4 f with curing degree of about 60%).

Techniques of curing photo-curable resin at the inner part in the gapbetween the cover plate 2 and the base are not limited in particular.Examples include: a technique of using an LED light source that can emitlong-wavelength light of about 400 nm wavelength, a technique of usingan optical lens or the like that can convert light beams into parallellight, and a technique of irradiating with the light source located in aposition parallel to the gap. From the point of making irradiation lightreach the inner part of the gap and stably curing the curable resin atthe inner part, it is preferable for this example to combine the abovetechniques to obtain a technique of irradiating light from a position inparallel to the gap by using a light source that can emitlong-wavelength light and an optical lens that can convert light beamsinto parallel light.

Next, as shown in FIG. 11D, the photo-curable resin at the edge part ofthe gap between the light-shielding member 3 of the cover plate 2 andthe wiring region 1 d of the base is cured with UV rays 8 (curable resin4 g of curing degree of 80% or more). Since photo-curable resin at theouter part in the gap between the light-shielding member 3 of the coverplate 2 and the wiring region 1 d of the base has been cured to someextent with UV rays 8 (UV rays with a long wavelength of about 400 nm)in FIG. 11C, the wavelength and illuminance level of UV rays 8 may beadjusted such that the curing degree is 80% or more as a result ofirradiation of the UV rays of this step.

Techniques of curing the photo-curable resin in the edge part of the gapbetween the cover plate 2 and the base is not limited in particular.Examples include: a technique of using an LED light source that can emitshort-wavelength light of about 360 nm; a technique of using an opticallens or the like that can condense light beams into a spot form; and atechnique of irradiating from obliquely downward of the gap. From thepoint of concentrating light at the end position of the gap and stablycuring the curable resin at the edge part of the gap, it is preferableto combine the above techniques in this example to obtain a technique ofirradiating from obliquely downward of the gap by using a light sourcethat can emit short-wavelength light and an optical lens that cancondense light beams into a sport form.

Next, another manufacturing method of the display apparatus of thisexample will be described with reference to FIGS. 12A to 12D.

First, as shown in FIG. 12A, the base and the cover plate 2 are adheredtogether by applying photo-curable resin onto at least one of the liquidcrystal panel 1 as the base and the cover plate 2 having thelight-shielding member 3; and adjusting positions of the base and thecover plate 2. Next, as shown in FIG. 12B, the photo-curable resin iscured with UV rays 8 up to the inner part of the gap between thelight-shielding member 3 of the cover plate 2 and the base (curableresin 4 f having a curing degree of about 60%). Similarly to the above,this step can be performed using the technique of irradiating thecurable resin from a position in parallel to the gap using a lightsource that can emit long-wavelength light of about 400 nm and anoptical lens that can convert light beams into parallel light. Next, asshown in FIG. 12C, photo-curable resin at the edge part of the gapbetween the light-shielding member 3 of the cover plate 2 and the baseis cured with UV rays 8 (curable resin 4 g of the curing degree of 80%or more). Similarly to the above, this step can be performed using atechnique of irradiating the curable resin from obliquely downward ofthe gap using a light source that can emit short-wavelength light ofabout 360 nm and an optical lens that can condense light beams into aspot form. Similarly to the above, the photo-curable resin in at theedge part of the gap between the light-shielding member 3 of the coverplate 2 and the base has been cured to some extent with UV rays 8 inFIG. 12B. Therefore, the wavelength and illuminance level of UV rays 8may be adjusted so as to cure the curable resin to have the curingdegree of 80% or more with irradiation of UV rays of this step. Next, asshown in FIG. 12D, the curable resin is irradiated with UV light 8 fromupward of the cover plate 2 or downward of the base (upward from thecover plate 2 in FIG. 12D) and the photo-curable resin located below thelight-transmission region 2 b of the cover plate 2 (cured curable resin4 e) is cured. Similarly to the above, this step can be performed using,for example, the technique of irradiating the cover plate 2 and thebase, which were adhered together, with a UV lamp while conveying themby a conveyor.

According to this method, it is possible to incorporate the steps inFIGS. 12A, 12B and 12C into the same manufacturing apparatus. Inaddition, by processing the step in FIG. 12B with the same manufacturingapparatus after adhering the cover plate 2 and the base together in FIG.12A, it is possible to also serve as temporary curing required in orderto prevent displacement of the cover plate 2 and the base upon conveyingthe adhered product to the next step after the adhering process.

Next, a method of manufacturing a display apparatus by usingheat-curable resin as curable resin 4 will be described with referenceto FIGS. 13A to 13D.

First, as shown in FIG. 13A, the base and the cover plate 2 are adheredtogether by applying heat-curable resin onto at least one of the liquidcrystal panel 1 as the base and the cover plate 2 having thelight-shielding member 3; adjusting positions of the base and the coverplate 2. Next, as shown in FIG. 13B, the heat-curable resin is curedwith far-infrared rays 9 b up to the inner part of the gap between thelight-shielding member 3 of the cover plate 2 and the base (curableresin 4 f having a curing degree of about 60%). Next, as shown in FIG.13C, heat-curable resin at the edge part the gap between thelight-shielding member 3 of the cover plate 2 and the base is cured withfar-infrared rays 9 a (curable resin 4 g of the curing degree of 80% ormore). Similarly to the above, the heat-curable resin at the edge partof the gap between the light-shielding member 3 of the cover plate 2 andthe base has been cured to some extent with far-infrared rays 9 b inFIG. 13B. Therefore, the wavelength and illuminance level offar-infrared rays 9 b may be adjusted so as to cure the curable resin tohave the curing degree of 80% or more with irradiation of far-infraredrays 9 b of this step. Next, as shown in FIG. 13D, the curable resin isirradiated with far-infrared rays 9 b from upward of the cover plate 2or downward of the base (upward from the cover plate 2 in FIG. 13D) andthe heat-curable resin located below the light-transmission region 2 bof the cover plate 2 (cured curable resin 4 e) is cured.

According to this process, it is possible to achieve the structures inFIGS. 1A to 10B described above even when heat-curable resin is used asthe curable resin 4.

Furthermore, a method of manufacturing a display apparatus by usinghybrid curable resin having moisture curability as the curable resin 4will be described with reference to FIGS. 14A to 14D.

Hybrid curable resin is curable resin 4 having moisture curabilityadditionally, such as photo-curability and heat-curability. When thehybrid curable resin having photo-curability and moisture-curability isused, it is possible to manufacture the display apparatus by combiningthe moisture curing process with the manufacturing method in FIGS. 11Ato 11D and 12A to 12D.

For example, as shown in FIG. 14A, the base and the cover plate 2 areadhered together by applying the hybrid curable resin onto at least oneof the liquid crystal panel 1 as the base and the cover plate 2 havingthe light-shielding member 3; and adjusting positions of the base andthe cover plate 2. Next, as shown in FIG. 14B, the hybrid curable resinis cured with UV rays 8 up to the inner part of the gap between thelight-shielding member 3 of the cover plate 2 and the base. Next, asshown in FIG. 14C, the hybrid curable resin at the edge part of the gapbetween the light-shielding member 3 of the cover plate 2 and the baseis cured by adding moisture 10. Next, as shown in FIG. 14D, the hybridcurable resin is irradiated with UV light 8 from upward of the coverplate 2 or downward of the base (upward from the cover plate 2 in FIG.14D) and the hybrid curable resin located below the light-transmissionregion 2 b of the cover plate 2 is cured.

According to this method, it is possible to achieve the structures inFIGS. 1A to 6B described above even when hybrid curable resin is used asthe curable resin 4.

Further, it is possible to achieve the structures in FIGS. 1A to 10Bdescribed above by combining the manufacturing methods of FIGS. 13A to13D and FIGS. 14A to 14D when hybrid curable resin having features ofthe heat-curability and the moisture-curability is used as the curableresin 4.

In FIGS. 11A to 14A, after curing the curable resin up to the inner partof the gap between the light-shielding member 3 of the cover plate 2 andthe base (namely, the entire curable resin shielded by thelight-shielding member 3), the curable resin at the end position of thegap between the light-shielding member 3 of the cover plate 2 and thebase is cured. Alternatively, it is also possible to cure the curableresin up to the inner position after curing the curable resin at theside of the end position in advance. In that case, the curable resin atthe side of the end position is further cured by the next curing step,and thus it is desirable to adjust the curing conditions in a previouscuring step in consideration of the curing in a later curing step.

Next, functioning of the display apparatus in Example 1 will bedescribed with reference to FIGS. 15A to 15D and 16A to 16D.

As shown in FIGS. 15A to 15D, it is assumed that external force 11 inthe separation direction is applied to either one of the cover plate 2and the base thus adhered together (cover plate 2 in this descriptionabout the functioning).

As shown in FIGS. 15A and 15B, the external force 11 in the separationdirection is applied to the edge region-curable part 4 a. However, sincethe edge region-curable part 4 a is sufficiently cured, it is hard toseparate because of the adhesion strength of the curable resin 4. Inaddition, even if the separation occurs, the inner curable-resin part 4b is in a non-fluidized state, and therefore the inner curable-resinpart 4 b does not flow out from the gap and does not contaminate thecover plate 2, the base, and the ambient surrounding thereof.

On the other hand, as shown in FIGS. 15C and 15D, if the curing degreeafter the curable resin 4 in the gap is cured is uniformly low,separation 13 of the cover plate 2 and the base from the curable resin 4occurs and air bubbles 12 are produced in the display region 1 e.Furthermore, if the curing is insufficient inside the gap, the uncuredportion of the curable resin 4 flows out so as to contaminate the coverplate 2, the base, and the ambient surrounding.

As shown in FIGS. 16A to 16D, it is assumed that external force 11 inthe pressing direction is applied by touch operation or the like ontoeither one of the cover plate 2 and the base thus adhered together(cover plate 2 in this operational description).

As shown in FIGS. 16A and 16B, the external force 11 in the pressingdirection is applied also to the inner curable-resin part 4 b in thegap. However, since the inner curable-resin part 4 b is sufficientlysoft, the inner curable-resin part 4 b absorbs stress coming from theexternal force and reduces the stress 11 a.

Meanwhile, as shown in FIGS. 16C and 16D, the stress transmitted to theliquid crystal panel 1 through the inner curable-resin part 4 b isfurther transmitted to the backlight chassis 15 a having a substratesupport 15 b supporting the end of the liquid crystal panel 1, and thestress 11 a received by the base is applied to the liquid crystal panel1 as a result of the stress concentrating on the parts where the liquidcrystal panel 1 and the backlight chassis 15 a contacted.

Here, the stress 11 a applied intensively from the substrate support 15b of the backlight chassis 15 a changes the height of the gap in theliquid crystal panel 1. However, since the stress 11 a is absorbed bythe inner curable-resin part 4 b so as to be smaller in the structure inFIGS. 16A and 16B, it merely produces slight wave-form display defects14. Meanwhile, as in FIGS. 16C and 16D, if the curing degree after thecurable resin 4 in the gap is cured is uniformly high such that elasticmodulus is high, the external force 11 in the pressing direction is notabsorbed, and the stress 11 a intensively applied from the substratesupport 15 b of the backlight chassis 15 a largely changes the height ofthe gap in the liquid crystal panel 1 and produces wave-form displaydefects 14.

As described above, since the curing degree, the elastic modulus andadhesion strength after the edge curable-resin part 4 a is cured aremade high relatively to the other parts in this example, it is difficultto separate the cover plate 2 and the base from the curable resin 4 dueto the external force 11 in the separation direction. Even if the coverplate 2 and the base are separated from the curable resin 4 with theexternal force 11 in the separation direction, the curable resin 4 doesnot flow out from the gap. Thus, there is an advantageous effect ofpreventing the cover plate 2, the base, and their ambient surroundingfrom contamination. In addition, since the curing degree, the elasticmodulus, and the adhesion strength after the inner curable-resin part 4b is cured are made low relatively to the other parts in this example,there is an advantageous effect that the display defect due to theexternal force 11 in the pressing direction tends not to be produced.

Example 2

Next, a display apparatus and a manufacturing method according toExample 2 will be described. The present example provides an examplethat the structure of the above-described embodiment is applied to thefollowing display apparatus. The display apparatus includes a base whichuses LCD module 15 for the image display region; cover plate 2 includinglight-shielding member 3; and curable resin 4 which is photo-curableresin. The entire surface of the base is adhered to the cover plate 2with the photo-curable resin 4. Hereinafter, the structure of Example 2will be described with reference to FIGS. 17A to 18B.

The base is an LCD module 15 and includes: a liquid crystal panel 1 thatdisplays images; a backlight chassis 15 a which has a liquid crystalpanel 1 and provides a light source for displaying and display signalsdownward; and a metal flame 15 c for protecting the liquid crystal panel1 and the backlight chassis 15 a. Since the structure of the liquidcrystal panel 1 is the same as that of Embodiment 1, the descriptionthereof will be omitted.

FIG. 17A is a plan view of the display apparatus, and FIG. 17B is asectional view of the display apparatus, taken along the lineXVIIB-XVIIB in FIG. 17A. FIG. 18A and FIG. 18B are a half sectional viewof the display apparatus and a graph of an example of the curing degreeof the curable resin with respect to distance along a gap between thebase and the cover plate 2.

As shown in FIGS. 17A and 17B, a metal flame 15 c of the LCD module 15is a flame that uses a light blocking metal plate or the like. The metalflame 15 c is arranged so as to cover the wiring region 1 d of theliquid crystal panel 1 and the outer edge part (peripheral part) of thebacklight chassis 15 a and a part corresponding to the display region 1e of the liquid crystal panel 1 is opened.

Photo-curable resin is used for the curable resin 4 for adhering thebase and the cover plate 2 having the light-shielding member 3 together.The gap between the base and the cover plate 2 is filled with thephoto-curable resin up to the outer edge of the metal frame 15 c. Thephoto-curable resin in the gap between the light-shielding member 3 ofthe cover plate 2 and the metal flame 15 c of the base is cured bylight. The photo-curable resin is cured as follows. The curing degree(or elastic modulus and adhesion strength), which is obtained after acuring process, of the inner curable-resin part 4 b located in thevicinity 3 b of the inner edge of the light-shielding member 3 (innerpart), differs from the curing degree (or elastic modulus and adhesionstrength), which is obtained after a curing process, of the edgecurable-resin part 4 a located a side 3 a of the outer edge of thelight-shielding member 3 (edge part). That is, the inner curable-resinpart 4 b is lower in curing degree (or elastic modulus and adhesionstrength) after a curing process than the edge curable-resin part 4 a.

For example, it is preferable that, as shown in FIGS. 18A and 18B, thecuring degree after a curing process of the inner curable-resin part 4 blocated nearby the display region 1 e of the base and in the vicinity 3b of the inner edge of the light-shielding member 3 is about 60%, whichis in a non-fluidized cured state, and the curing degree after a curingprocess of the edge curable-resin part 4 a located at a side 3 a of theouter edge of the light-shielding member 3 is equal to 80% or more,which is in a cured state.

In the structure of this example, functioning of the display apparatuswhen external force in the pressing direction is applied onto either oneof the cover plate 2 and the base adhered together by a touch operationor the like (see the functioning shown in FIGS. 16A and 16B) is the sameas Example 1.

In the functioning of the display apparatus (the functioning in FIGS.15A and 15B) when external force 11 in the separation direction isapplied to one of the cover plate 2 and the base adhered together,separation hardly occurs as a result of the adhesion strength of thesufficiently cured edge curable-resin part 4 a. Further, the gap betweenthe light-shielding member 3 of the cover plate 2 and the metal flame 15c of the base is filled with the photo-curable resin up to the end ofthe metal flame 15 c. Accordingly, the area where the curable resin 4contacts with the cover plate 2 and the metal flame 15 c increases, andthus it is possible to increase regions having high curing degree, whichincreases the adhesion strength.

As described above, in addition to the advantageous effect of Example 1,this example has an advantageous effect that separation of the coverplate 2 and the base hardly occurs due to the external force 11.

Example 3

Next, a display apparatus and a manufacturing method according toExample 3 will be described. The present example provides an examplethat the structure of the above-described embodiment is applied to thefollowing display apparatus. Additionally to the structure of Example 1,the display apparatus further includes gap-forming member 16 in a gapbetween the base and the cover plate 2. The entire surface of the baseis adhered to the cover plate 2 with the photo-curable resin.

Hereinafter, the structure of Example 3 will be described with referenceto FIGS. 19A to 20B. Since the base and the cover plate 2 are the sameas that of Example 1, the description thereof will be omitted.

FIG. 19A is a plan view of the display apparatus, and FIG. 19B is asectional view of the display apparatus, taken along the line XIXB-XIXBin FIG. 19A. FIG. 20A and FIG. 20B are a half sectional view of thedisplay apparatus and a graph of an example of the curing degree of thecurable resin with respect to distance along a gap between the base andthe cover plate 2.

As shown in FIGS. 19A and 19B, the gap-forming member 16 is provided inthe gap between the base and the cover plate 2 on the periphery of thedisplay region 1 e (in the present example, above the seal 1 g of theliquid crystal panel 1) and has thickness such that the gap between thebase and the cover plate 2 becomes a predetermined height. Specifically,the distance between the cover plate 2 and the base is preferably 0.1 mmor more, and more preferably, about 0.5 mm. This is because elasticityof the curable resin 4 at about 0.5 mm hardly causes the separation ofthe cover plate 2 and the base due to external force, and the curableresin 4 at about 1 mm uses the large amount of resin and increases thecost.

Example of the material used for the gap-forming member 16 includecurable resin and double-faced adhesion tape that is cured with light,heat, humidity, or the like. Among those, transparent photo-curableresin material (that has refractive index equivalent to that of thephoto-curable resin for adhering the base and the cover plate 2together) is preferable from the point of the degree of freedom withrespect to the thickness, workability and visibility.

Photo-curable resin is used for the curable resin 4 for adhering thebase and the cover plate 2 having the light-shielding member 3 together.The gap between the base and the cover plate 2 is filled with thephoto-curable resin up to the outer edge of the base, where the amountof the photo-curable resin to be used is defined on the basis of theheight of the gap-forming member 16. The photo-curable resin in the gapbetween the light-shielding member 3 of the cover plate 2 and the baseis cured by light, so as to be separated by the gap-forming member 16into the inner curable-resin part 4 b located in the vicinity 3 b of theinner edge of the light-shielding member 3 (inner part) and the edgecurable-resin part 4 a located a side 3 a of the outer edge of thelight-shielding member 3 (edge part). The photo-curable resin is curedas follows. The curing degree (or elastic modulus and adhesionstrength), which is obtained after a curing process, of the innercurable-resin part 4 b differs from the curing degree (or elasticmodulus and adhesion strength), which is obtained after a curingprocess, of the edge curable-resin part 4 a. That is, the innercurable-resin part 4 b is lower in curing degree (or elastic modulus andadhesion strength) after a curing process than the edge curable-resinpart 4 a.

For example, it is preferable that, as shown in FIGS. 20A and 20B, thecuring degree after a curing process of the inner curable-resin part 4 blocated nearby the display region 1 e of the base and in the vicinity 3b of the inner edge of the light-shielding member 3 is about 60%, whichis in a non-fluidized cured state, and the curing degree after a curingprocess of the edge curable-resin part 4 a located a side 3 a of theouter edge of the light-shielding member 3 is equal to 80% or more,which is in a cured state.

In the structure of this example, when external force 11 in theseparation direction is applied to either one of the cover plate 2 andbase adhered together, the amount of elastic deformation increasesbecause of the thickness of the curable resin 4 increasing with thegap-forming member 16 provided in the gap between the light-shieldingmember 3 of the cover plate 2 and the base. Thus, it is possible toincrease adhesion strength.

On the other hand, when external force in the pressing direction isapplied on either one of the cover plate 2 and base adhered togetherwith a touch operation or the like, the external force in the pressingdirection is applied to the curable resin 4 inside the gap. However,since the curable resin 4 is sufficiently soft and furthermore thethickness of the soft curable resin 4 increases, the amount ofabsorption of the stress due to the elastic deformation of the curableresin 4 increases, and thus the display defect tends not to occur.

As described above, in this example, there is an advantageous effectthat separation of the cover plate 2 and the base hardly occurs due toexternal force and that the display defects hardly occurs due to theexternal force in the pressing direction, in comparison with the case ofExample 1.

Example 4

Next, a display apparatus and a manufacturing method according toExample 4 will be described. The present example provides an examplethat the structure of the above-described embodiment is applied to thefollowing display apparatus. Additionally to the structure of Example 1,the curing degree (or elastic modulus and adhesion strength) after acuring process of the display-region curable-resin part 4 c located inthe display region 1 e is made higher than the curing degree (or elasticmodulus and adhesion strength) after a curing process of the innercurable-resin part 4 b.

Hereinafter, the structure of Example will be described with referenceto FIGS. 21A to 23B. Since the structure of the curable resin 4 of thegap between the base and the cover plate 2 is the same as that ofExample 1, the description thereof is omitted.

As shown in FIGS. 21A to 23B, the curing degree (or elastic modulus andadhesion strength), which is obtained after a curing process, of theinner curable-resin part 4 b located in the vicinity 3 b of the inneredge of the light-shielding member 3 (inner part), differs from thecuring degree (or elastic modulus and adhesion strength), which isobtained after a curing process, of the edge curable-resin part 4 alocated a side 3 a of the outer edge of the light-shielding member 3(edge part). That is, the inner curable-resin part 4 b is lower incuring degree (or elastic modulus and adhesion strength) after a curingprocess than the edge curable-resin part 4 a. Further, thedisplay-region curable-resin part 4 c located below the display region 1e is higher in curing degree (or elastic modulus and adhesion strength),which is obtained after a curing process than the inner curable-resinpart 4 b.

For example, as shown in FIGS. 21A and 21B, in the structure that thedisplay-region curable-resin part 4 c located below the display region 1e is higher in curing degree, which is obtained after a curing processthan the edge curable-resin part 4 a located at a side 3 a of the outeredge of the light-shielding member 3, the adhesion strength of the coverplate 2 and the base is such that the adhesion strength of thedisplay-region curable-resin part 4 c of is higher than the edgecurable-resin part 4 a. Even if the edge curable-resin part 4 a and theinner curable-resin part 4 b are separated when the external force inthe separation direction is applied onto either one of the cover plate 2and base adhered together, the display-region curable-resin part 4 c isnot separated, which can restricts occurrence of air bubbles in thedisplay region 1 e. It should be noted that, in FIGS. 21A and 21B, thecuring degree after a curing process of the display-region curable-resinpart 4 c may be equal to the curing degree after a curing process of theedge curable-resin part 4 a.

As shown in FIGS. 22A and 22B, in the structure that the display-regioncurable-resin part 4 c located below the display region 1 e is lower incuring degree, which is obtained after a curing process, than the edgecurable-resin part 4 a and is higher in curing degree, which is obtainedafter a curing process, than the inner curable-resin part 4 b, evenunder the condition that external force in the pressing direction isapplied to the display region 1 e, the display-region curable-resin part4 c absorbs stress and the display defects hardly occurs since thedisplay-region curable-resin part 4 c in the display region 1 e is soft.It should be noted that, in FIGS. 22A and 22B, the curing degree after acuring process of the display-region curable-resin part 4 c cures may beequal to the curing degree after a curing process of the innercurable-resin part 4 b.

As shown in FIGS. 23A and 23B, the display-region curable-resin part 4 cbelow the display region 1 e may be cured with UV rays such that thecurable resin 4 below the light-shielding member 3 is cured to partlyhave a high curing degree, which can provide the same effect as thestructure shown in FIGS. 21A and 21B.

As described above, this example has an advantageous effect that theseparation of the cover plate 2 and the base hardly occurs due toexternal force 11 and the display defects hardly occur due to externalforce 11 in the pressing direction in comparison with Example 1.

It should be noted that the present invention is not limited to theabove-described embodiments and examples. For example, Example 3 can beapplied to any example described in Example 1 and Example 2. Inaddition, Example 4 can be applied to and combined with any example thatuses an image display unit for the base among Examples 1 to 3.Furthermore, with respect to the base, the cover plate 2 and curableresin 4, elements exemplified in Examples 1 can be combined freely toapply to Examples 2 to 4.

The invention claimed is:
 1. An apparatus comprising: a plate-shapedbase; a cover plate; a curable resin located in a gap between theplate-shaped base and the cover plate and adhering the plate-shaped baseand the cover plate together; and a light-shielding member located on aperipheral part of at least one of the plate-shaped base and the coverplate, wherein the curable resin includes a first curable-resin part, asecond curable-resin part, and a third curable-resin part, the firstcurable-resin part, the second curable-resin part, and the thirdcurable-resin part are arranged from an outside of the apparatus towardan inside of the apparatus, the first curable-resin part contacts thesecond curable-resin part, the second curable-resin part contacts thethird curable-resin part, the first curable-resin part and the secondcurable-resin part are shielded by the light-shielding member, the thirdcurable-resin part is not shielded by the light-shielding member, thesecond curable-resin part is lower in one of an elastic modulus, and anadhesion strength than the first curable-resin part, and the thirdcurable-resin part is higher or a substantially same in one of anelastic modulus, and an adhesion strength, in comparison with the firstcurable-resin part.
 2. The apparatus of claim 1, wherein the one of anelastic modulus, a curing degree, and an adhesion strength of the firstand second curable-resin parts decreases continuously from the outeredge of the light-shielding member to the inner edge of thelight-shielding member.
 3. The apparatus of claim 1, wherein the elasticmodulus of the second curable-resin part is equal to 5 KPa or less. 4.The apparatus of claim 1, wherein the second curable-resin part has acuring degree of about 60%, and the first curable-resin part has acuring degree equal to 80% or more.
 5. The apparatus of claim 1, whereinthe curable resin has at least one of photo-curability, heat-curability,and moisture-curability.
 6. The apparatus of claim 1, wherein the gap isfilled with the curable resin up to the end of the plate-shaped base. 7.The apparatus of claim 1, further comprising a gap-forming memberlocated in the gap between the plate-shaped base and the cover plate. 8.The apparatus of claim 7, wherein the gap-forming member is located at aposition between the outer edge and the inner edge of the area in thegap, which is shielded by the light-shielding member, to separate thefirst curable-resin part and the second curable-resin part from eachother.
 9. The apparatus of claim 1, wherein the plate-shaped baseincludes an image display unit or an input unit.
 10. The apparatus ofclaim 9, wherein the plate-shaped base includes an image display unit,the image display unit includes substrates facing each other, a sealjoining the substrates together, and liquid crystal sealed within aspace inside the seal, the second curable-resin part is located in thegap to cover an area from the inner edge of the light-shielding memberto an inner edge of the seal, and the first curable-resin part islocated in the gap to cover an area from the inner edge of the seal tothe outer edge of the light-shielding member.
 11. The apparatus of claim1, wherein the cover plate includes an input unit, a substrate, or acomposite substrate.
 12. The apparatus of claim 1, wherein the secondcurable-resin part is interposed between the first curable-resin partand the third curable-resin part.
 13. The apparatus of claim 12, whereinthe first curable-resin part includes an end of the curable resin. 14.The apparatus of claim 1, wherein the light-shielding member has auniform property over a whole region of the light-shielding member. 15.The apparatus of claim 1, wherein a curing degree changes step-wisebetween the first curable-resin part and the second curable-resin part.